KR102249722B1 - Wireless charging power supply system during running of electric vehicles and industrial equipment - Google Patents

Abstract

The present invention relates to a wireless charging and feeding system, and more particularly, to a wireless charging and feeding system during operation of electric vehicles such as electric buses, electric passenger cars, trams, light railroads, subways, and industrial equipment including RTGC (Rubber Tyred Gantry Crane). About.
According to the present invention, it is possible to expand the wireless power supply line while driving by solving the problem of withstand voltage on the conventional power supply line with a capacitor provided in a'box'or'inverter' existing outside the road, a design method for a power supply line, and a common line arrangement design. And, according to this scalability, the economic problem of the wireless charging system is greatly improved. In addition, in contrast to the method of maintaining compatibility with various wireless charging collection pads installed in the vehicle while driving by using a conventional method of using a plurality of inverters, the use of the relays in the'box'and'inverter' makes it more affordable. It provides a wireless charging and power supply system that satisfies the same compatibility sufficiently, and further reduces the EMI (ElectroMagnetic Interference) of the power supply line by maximizing the magnetic field cancellation effect by using a common line structure and shielding tube.

Description

Wireless charging power supply system during running of electric vehicles and industrial equipment

The present invention relates to a wireless charging and feeding system, and more particularly, to a wireless charging and feeding system during operation of electric vehicles such as electric buses, electric passenger cars, trams, light railroads, subways, and industrial equipment including RTGC (Rubber Tyred Gantry Crane). About.

Due to global warming, the use of electric power using batteries as an energy source is increasing for transportation means such as automobiles and railroads to replace petroleum energy. However, due to insufficient battery capacity, short driving distance and frequent charging are required, there has been a limit to the spread of electric vehicles more generally due to the lack of infrastructure such as charging stations and the need for charging time. A power supply system is also being installed to enable wireless charging on the road.

1 is a view showing a power supply line of a wireless charging system 100 while driving a conventional wireless charging electric vehicle, the power supply line is placed on the left and right sides around the inverter 101 and is composed of a single coil.

In the inverter 110, a sinusoidal current is applied to a feed line composed of the common line portion 130 and the feed region 140, and the applied current returns to the inverter 110 again.

In this configuration, it is possible to wirelessly charge electric vehicles and industrial equipment by configuring a power supply line without much difficulty in a low frequency range (20 to 40 kHz). However, due to the limitation of wireless charging, which is relatively expensive compared to wired charging, and the weight and size of the wireless charging pad installed in the vehicle, the frequency of wireless charging is being changed from 20 to 40 kHz to 85 kHz through many studies. However, depending on the changed frequency, advantages can also be secured, but it has the disadvantage that the withstand voltage problem due to frequency rise always exists.

That is, if the frequency is increased from 20 to 40 kHz to 85 kHz according to the current wireless charging trend for electric vehicles, the internal pressure between both ends of the same feed line increases by about 4.25 times, which may cause problems such as discharge and leakage current. In order to suppress this, a method of shortening the teeth of the feed line or reducing the current used may be proposed, but if the length is shortened, the charging time of the charging electric vehicle while driving is shortened, resulting in a problem that the charging amount is significantly reduced. Reducing the current may be one solution, but when the current is reduced, a voltage lower than the battery voltage is formed by the excitation electromotive force, and thus, there is a problem in that charging the battery becomes difficult.

In addition to the frequency problem, in the case of the conventional wireless charging and feeding system 100 while driving an electric vehicle, a single coil is wound in one turn in the vehicle traveling direction, so that compatibility with a wireless charging pad attached to another vehicle may be lacking. Have.

US 9,533,590 B2

The present invention has been invented to solve such a problem, and improves compatibility with various wireless charging and collecting pads installed in vehicles in a way that more effectively reduces the internal pressure of the power supply line and further reduces the cost, and also improves the compatibility with the various wireless charging and collecting pads installed in the vehicle. Its purpose is to provide a wireless charging and feeding system that reduces EMI (ElectroMagnetic Interference).

In order to achieve such an object, a system for controlling charging power wirelessly while driving of an electric vehicle equipped with a current collector according to the present invention and industrial equipment (hereinafter collectively referred to as'electric vehicle') is wirelessly controlled by an alternating current flow. A feed cable for generating electric power for charging; An inverter including a relay that controls the supply of the AC current flowing through the feed cable and adjusts the phase of the AC current to 0 degrees or 180 degrees; And a capacitor unit including a relay for adjusting the phase of the AC current to 0 degrees or 180 degrees under the control of the inverter, and a capacitor for canceling an inductance of a power supply line, and the other end of the power supply cable connected to the inverter. Is configured to be connected to the next capacitor unit without returning to the inverter.

One or more capacitor units are provided, and when two or more capacitor units are provided, the other end of the power supply cable having one end connected to the nth capacitor unit is connected to the n+1th capacitor unit without returning to the nth capacitor unit. I can.

The coil constituting the power supply cable may be composed of one pair, or may be composed of two or more pairs.

A power feeding core which is a ferromagnetic material may be further included in the lower portion of the power supply cable.

When the power supply cable is composed of n (n≥2) pairs of coils, each coil can independently adjust the phase of the current by a relay, so that all of the phases of 0 degrees or 180 degrees for the n pairs of coils Combination is possible, and wireless power supplied through the feed cable may be controlled by controlling the current phase combination.

When the feed cable is composed of n (n≥2) pairs of coils, each coil may be disposed to be in contact without a spacing distance, or may be disposed to be separated by a predetermined distance.

The coil and the feed core constituting the feed cable may be disposed to be in contact without a distance, or may be disposed to be spaced apart from each other by a predetermined distance.

Each coil in a section (hereinafter referred to as a'common line') in which the coils constituting the feed cable are gathered may have a current direction set so as to cancel a magnetic field above a preset reference.

The wireless charging and feeding system for the electric vehicle may further include a shielding tube surrounding the entire coil for magnetic field shielding in a section where each coil constituting the feeding cable is gathered (hereinafter referred to as a'common line'). .

When the electric vehicle enters the power supply section, the inverter detects the location of the entered electric vehicle, detects information on the current collector installed in the electric vehicle, and the electric vehicle is located according to the detected current collector information. The power of the point can be controlled, and when the electric vehicle leaves the location, the power of the location can be cut off.

The location of the electric vehicle may be a feed segment in which the electric vehicle is located.

The information on the current collecting device may be a type of the current collecting device or a height of the current collecting device from the ground.

According to another aspect of the present invention, the method of controlling the power supply in the wireless charging and power supply system includes: (a) the inverter, when an electric vehicle equipped with a current collector enters the power supply section controlled by the inverter, the corresponding electricity Detecting the position of the vehicle; (b) determining, by the inverter, information on a current collector installed in the electric vehicle; (c) converting, by the inverter, a point at which the electric vehicle is located into a charging mode, and controlling power to be supplied to the position according to the determined current collecting device information; And (d) the inverter, when the electric vehicle leaves the location, switching the location to an off mode to cut off power at the location.

The location of the electric vehicle may be a feed segment in which the electric vehicle is located.

The information on the current collecting device may be a type of the current collecting device or a height of the current collecting device from the ground.

When the power supply cable is composed of n (n≥2) pairs of coils, each coil can independently adjust the phase of the current by means of a relay, so all combinations of 0 degree or 180 degree phases for the n pairs of coils This is possible, and the inverter may control the wireless power supplied through the feed cable by controlling the current phase combination.

According to the present invention, it is possible to expand the wireless power supply line while driving by solving the problem of withstand voltage on the conventional power supply line with a capacitor provided in a'box' or'inverter' existing outside the road, a design method for a power supply line, and a common line arrangement design. And, according to this scalability, there is an effect of greatly improving the economic problem of the wireless charging system.

In addition, in contrast to the method of maintaining compatibility with various wireless charging collection pads installed in the vehicle while driving by the method of using a number of inverters in the related art, the use of relays in the'box' and'inverter' makes it more affordable. There is an effect of providing a wireless charging and feeding system that satisfies the same compatibility sufficiently.

Furthermore, there is an effect of reducing the EMI (ElectroMagnetic Interference) of the feeding line by maximizing the magnetic field cancellation effect by using the structure of the common line and the shielding tube.

1 is a view showing a feed line of a conventional wireless charging and feeding system.
Figure 2 is a schematic diagram showing a wireless charging and feeding system including an electric vehicle on the road according to the present invention.
3 is a view showing the coil structure of the feed line of the wireless charging and feeding system according to the present invention.
4 is a view showing the shape and structure of a ferromagnetic material forming a power feeding core of the wireless charging and feeding system according to the present invention.
5 is a diagram showing a distance between coils, which is a design variable of a wireless charging and feeding system according to the present invention, and a distance between a coil and a ferromagnetic material, which is a feed core.
6 is a graph showing a change in inductance per unit distance of a feed line according to the design variables shown in FIG. 5;
7 is a diagram illustrating a method of processing a common line portion in the wireless charging and feeding system according to the present invention.
8 is a flow chart showing a power supply control method in the wireless charging and power supply system according to the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors appropriately explain the concept of terms in order to explain their own invention in the best way. Based on the principle that it can be defined, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention. Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all the technical spirit of the present invention. It should be understood that there may be equivalents and variations.

2 is a schematic diagram showing a wireless charging and feeding system including an electric vehicle on a road according to the present invention.

In the wireless power transmission of the electric vehicle (bus, tram, train, passenger car, etc.) 10, the wireless charging and feeding system 200 according to the present invention includes a power supply unit composed of a plurality of power supply pads, and a power supply unit. It includes an inverter 210 supplying AC power, and a common line 230 connecting the inverter 210 and the power supply unit. The power supply unit includes a power supply core and a power supply cable 240 made of a ferromagnetic material.

The configuration of the inverter 210 or the box 220 of the wireless charging and feeding system 200 of the present invention is not limited to the inverter or the box, but may be accompanied by a switch or other power device, and these devices are also through the inverter or the box. Since it is a device that implements the same functions as those implemented, these will be collectively referred to as the inverter 210 and other boxes 220 in the following description. Here, the term'box' refers to a box including a circuit unit including a capacitor and a relay, and hereinafter, this will be referred to as a'capacitor unit 220' by separating it from the inverter 210. Such a relay is also provided in the inverter 210.

In addition, in the present invention, the common line connecting the power supply unit and the inverter is not returned, and as shown in FIG. 2, the structure is extended and connected to the next inverter or capacitor unit 220. Likewise, even when two or more capacitor units 220 are provided (221, 222...), the other end of the power feeding cable connected to the nth capacitor unit, as shown in FIG. 2, returns to the nth capacitor unit. It is connected to the n+1th capacitor part without doing so.

The wireless charging and feeding system 200 of the present invention of FIG. 2 includes a feed line having compatibility so that charging is possible even when various types of wireless charging pads are attached to various types of vehicles. When the power supply line is configured as shown in FIG. 2, the breakdown voltage of the power supply line may be more effectively reduced through a capacitor provided in the inverter 210 or a capacitor provided in the capacitor unit 220. The reason why the internal pressure of the power supply line can be reduced is that the capacitor cancels the inductance generated in the power supply line.

Further, an advantage of the present invention is that a plurality of inverters are not used to implement the compatibility as described above. In other words, when a plurality of inverters are used, the cost of installation is so high that economic feasibility decreases. In the present invention, such compatibility is sufficiently secured through one inverter 210 and one or more capacitor units 220 connected to the inverter 210 as shown in FIG. 2, that is, the inverter 210 or the capacitor. By changing the current phase through the relay disposed in the unit 220, it is possible to ensure compatibility. A method of implementing such compatibility will be described later in detail with reference to FIG. 3.

In addition, the shape of the feed line of the wireless charging and feeding system 200 may be in various shapes including an oval or circular structure, and may be accompanied by a ferromagnetic material such as a ferrite core as a feed core, or may not be accompanied by a ferromagnetic material as a feed core, When a ferromagnetic material as a power feeding core is provided, an embodiment of the shape of such a ferromagnetic material will be described later with reference to FIG. 4.

In addition, the coil structure of the power supply line may include one coil as a pair or two or more pairs, and an example thereof is illustrated in FIG. 3.

In the case of a feed line composed of two or more pairs of coils, the current direction of each coil of the feed line can be made in all possible combinations of the coils, and the spacing of a pair of coils or two or more pairs of coils is at various intervals including equal intervals It may include, which will be described later with reference to FIGS. 3 and 5.

3 is a diagram showing a coil structure of a feed line of the wireless charging and feeding system 200 according to the present invention, and FIG. 4 is a shape and structure of a ferromagnetic material forming a feed core of the wireless charging and feeding system 200 according to the present invention. The shape and structure of the ferromagnetic material may include all of the modified shapes, including bar-type, L-type, and W-type.

In FIG. 3, an embodiment 300 of a cross-section of a power supply cable 240 constituting a power supply line, that is, a cross-section showing the direction of current flowing in the power supply cable 240 is shown.

As in the cross-sectional embodiment 300, the feed line may be composed of a single coil 301 or a plurality of coils 302,303,304. In this drawing, the direction of the current is indicated by'·' and the direction of the current is indicated by'X'. In this drawing, only three examples of 301, 302, and 303 are shown for the case of using two coils, but it goes without saying that any combination of two'·' and two'X' is possible.

According to the control of the relay of the inverter 210 and the relay of the capacitor unit 220, the direction of the current in each coil can be controlled as'·' or'X'. That is, according to the control of the relay of the inverter 210 and the relay of the capacitor 220, the phase of the current in each coil can be controlled to 0 or 180 degrees.

By controlling the phase of each coil as described above, wireless power by magnetic flux transmitted to the upper portion of the corresponding feed line section may be generated to enter a charging mode, or power may be cut off (off mode) by blocking the magnetic flux. For example, in the case of 302 in FIG. 3, wireless power is generated by magnetic flux from the current of the power supply cable 240, thereby entering the charging mode. However, in the case of 303, one pair of coils on the left cancels each other as currents of opposite phases, so that no power for charging is generated. Likewise, the pair of coils on the right side does not generate power.

In this way, the phase control of the current can be variously controlled in addition to switching to the charging mode or the off mode. For example, in the case of 303 or 304 of FIG. 3, even if a pair of coils on the left have opposite current phases, power may be generated at the receiving side to some extent according to the distance 20 between the two coils. That is, if the two coils are arranged very close, the power of the receiving side will hardly be generated, but the power of the receiving side generated increases as the distance between the two coils is separated by a predetermined interval or more. As described above, according to the distance 20 between the coils and the distance between the coil 240 and the lower power feeding core 250 (30, see FIG. 5), it occurs when a current of the same phase flows through a pair of coils on both sides. The power and the power generated when the current of the opposite phase flows change.

The inverter 210 that controls the magnitude and phase of the generated current not only controls the generation of wireless power in the corresponding section as on or off depending on the presence or absence of a vehicle in a specific segment of the feed line section, as well as the corresponding section It detects the type of pick-up device mounted on the vehicle passing through the road and the height of the current collector from the ground of the feeder line, which varies depending on the type of vehicle passing through the vehicle, etc., so that appropriate wireless power is supplied to the corresponding current collector. It is possible to control the phase of the current flowing through the feed cable 240 of the feed line, that is, the coil 240 as shown in the embodiment 300 of FIG. 3.

The control of the phase of the current by the inverter 210 is performed by controlling a relay provided in the inverter 210 and a relay provided in the capacitor unit 220 of each section.

That is, when the power supply cable 240 is composed of n (n≥2) pairs of coils, each coil can independently adjust the phase of the current by the relay under the control of the inverter 210, so that n pairs of All combinations of phases of 0 degrees or 180 degrees with respect to the coil are possible, and wireless power supplied through the feed cable is controlled by controlling the current phase combination of the inverter 210 as described above.

As described above, it is'compatibility' as described above to automatically control and supply an appropriate amount of wireless power for charging, as described above, for various types of current collectors and installation heights of various current collectors.

In addition, the inductance of the feed line can be reduced by controlling the phase.

5 is a diagram showing the distance 20 between the coil 240, which is a design variable of the wireless charging and feeding system 200 according to the present invention, and the distance 30 between the coil 240 and the ferromagnetic material 250, which is a feeding core. , FIG. 6 is a graph showing the change in inductance per unit distance of the feed line according to the design variable shown in FIG. 5.

5 shows a method for securing compatibility according to the spacing between coils constituting a feed line and extending a section due to inductance reduction. Advantageous conditions can be determined by converting the inductance value according to the change in the distance between the coils 20 and the distance 30 between the coil and the ferromagnetic material into a unit distance. That is, each coil may be disposed to be in contact without a distance, or may be disposed at a certain distance apart, and the coil and the feed core constituting the feed cable may also be disposed to contact without a distance, or may be disposed at a certain distance apart. have.

In FIG. 6, the F15 graph 61 indicates that the separation distance 30 between the ferromagnetic material and the coil is 15 mm, and F25 indicates that the separation distance 30 between the ferromagnetic material and the coil is 25 mm (62). In addition, the value of the x-axis (horizontal axis) of the graph represents the distance 20 between coils, and the y-axis (vertical axis) represents inductance per unit length.

The 66 points on each graph in the graph show examples of a total of 66 designs for the design variables (20, 30) of the interval. Can be set.

7 is a diagram illustrating a method of processing the common line 230 in the wireless charging and feeding system 200 according to the present invention.

The common line refers to a portion where the feed cable 240 is gathered, that is, a portion 230 (see FIG. 2) where the feed cable is gathered from the inverter 210 or the capacitor unit 220. The common line 230 is enclosed by the shielding tube 260 to shield the magnetic field, as well as to maximize the magnetic field cancellation effect by adjusting the direction of the current as shown in FIG. 7(b) to reduce the inductance.

8 is a flow chart showing a power supply control method in the wireless charging and power supply system 200 according to the present invention.

The control of FIG. 8 is performed by the inverter 210. When the electric vehicle 10 equipped with a current collector enters the power supply section controlled by the inverter 210, the location of the vehicle is sensed (S801). The feed section controlled by the inverter means all the capacitor units 220 connected to the corresponding inverter 210 and the feed cable section connected thereto. The position of the vehicle to be detected means that it is to determine which feed segment is located within the feed section. The feed segment is a feed line between the inverter 210 and the next capacitor unit 221 (see FIG. 2), and the feed line between the next capacitor unit 221 (see FIG. 2) and the next capacitor unit 222 (see FIG. 2). Etc. Referring to FIG. 2, the feed line between the inverter 210 and the next capacitor unit 221 (see FIG. 2) is referred to as a first feed segment, and the next capacitor unit 221 (see FIG. 2) and the next capacitor unit 222 , See FIG. 2) as a second feed segment, the vehicle is in a state in which the vehicle has entered the second feed segment.

Such location detection (S801) may be performed in various ways, but as an embodiment, a method of receiving GPS information of the vehicle 10 and identifying a feeding segment within the feeding section of the current inverter 210 of the vehicle is used. I can. Alternatively, the inverter 210 connected to the power supply segment in which the vehicle 10 is located directly detects vehicle entry, or the capacitor units 221 and 222 connected to the power supply segment detect vehicle entry and transmit a signal to the inverter 210. can send.

Thereafter, the inverter 210 connected to the power supply segment in which the vehicle 10 is located directly detects information on the current collector installed in the vehicle 10, or the capacitor units 221 and 222 connected to the power supply segment, etc. 10) The information on the current collector is sensed and the information is sent to the inverter 210, so that the inverter 210 can grasp the information on the current collector (S802). The current collecting device information may include the type of the current collecting device, the height of the current collecting device from the ground, and the like.

The inverter 210 switches the power supply segment in which the vehicle is located to the charging mode and controls power to be supplied according to the current collector information (S803). Such power control, as described above with reference to FIG. 3, controls the relay of the inverter 210 and the capacitor unit 221 or 222 of the corresponding feed segment to control the phase of the current of each coil 240. You can do it the way.

Subsequently, when the driving vehicle 10 exits the feed segment, the inverter 210 switches the feed segment to the off mode to cut off the power of the feed segment (S804). The power supply segment may also cut off power by controlling the relay of the capacitor unit 221 or 222 of the corresponding power supply segment to control the phase of the current of each coil 240.

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those of ordinary skill in the art to which the present invention pertains. It goes without saying that various modifications and variations are possible within the equivalent range of the claims to be described.

10: Electric vehicle equipped with current collector
20: distance between feed coils
30: distance between the feed coil and the feed core
100: conventional inverter
110: conventional feed line
200: wireless charging and feeding system of the present invention
210: inverter
220: capacitor part
221: first capacitor unit
222: second capacitor unit
230: common line
240: feed cable
250: feed core
260: common line shielding tube

Claims (16)

As a system that wirelessly controls charging power while driving electric vehicles and industrial equipment (hereinafter referred to as'electric vehicles') equipped with a current collector,
A feed cable for generating electric power for wireless charging by flowing an alternating current;
An inverter including a relay that controls the supply of the AC current flowing through the feed cable and adjusts the phase of the AC current to 0 degrees or 180 degrees; And,
A capacitor unit including a relay that adjusts the phase of the AC current to 0 degrees or 180 degrees under the control of the inverter, and a capacitor that cancels the inductance of the feed line
Including,
The other end of the feed cable having one end connected to the inverter is configured to be connected to the next capacitor unit without returning to the inverter,
Wireless charging and feeding system for an electric vehicle comprising a. The method according to claim 1,
One or more capacitor units are provided,
When two or more capacitor units are provided,
The other end of the power supply cable having one end connected to the nth capacitor unit is connected to the n+1th capacitor unit without returning to the nth capacitor unit,
A wireless charging and feeding system for an electric vehicle, characterized in that. The method according to claim 2,
The coil constituting the feed cable,
Consisting of one pair, or consisting of two or more pairs
A wireless charging and feeding system for an electric vehicle, characterized in that. The method of claim 3,
Further comprising a feed core, which is a ferromagnetic material, under the feed cable
A wireless charging and feeding system for an electric vehicle, characterized in that. The method according to claim 3 or 4,
When the power supply cable is composed of n (n≥2) pairs of coils,
Each coil can independently adjust the current phase by means of a relay,
Any combination of 0 degree or 180 degree phase is possible for the n pairs of coils,
Controlling wireless power supplied through a feed cable by controlling the current phase combination
A wireless charging and feeding system for an electric vehicle, characterized in that. The method according to claim 3 or 4,
When the power supply cable is composed of n (n≥2) pairs of coils,
Each coil is arranged to be in contact without a separation distance, or arranged at a certain distance apart.
A wireless charging and feeding system for an electric vehicle, characterized in that. The method of claim 4,
The coil and the feed core constituting the feed cable,
Arranged to be in contact without a separation distance, or arranged at a certain distance apart
A wireless charging and feeding system for an electric vehicle, characterized in that. The method according to claim 2,
Each coil in the section (hereinafter referred to as'common line') in which each coil constituting the feed cable is gathered is set in a current direction so that the magnetic field is canceled above a preset standard.
A wireless charging and feeding system for an electric vehicle, characterized in that. The method according to claim 2,
In the section where each coil constituting the feed cable is gathered (hereinafter referred to as'common line'), a shielding tube surrounding the entire coil for magnetic field shielding
A wireless charging and feeding system for an electric vehicle, characterized in that it further comprises. The method of claim 5,
The inverter,
When the electric vehicle enters the power supply section, the location of the entered electric vehicle is sensed, information on the current collector installed in the electric vehicle is sensed, and the electric power at the point where the corresponding electric vehicle is located is determined according to the detected current collector information. Controlling and controlling to cut off power at that location when the electric vehicle leaves the location
A wireless charging and feeding system for an electric vehicle, characterized in that. The method of claim 10,
The location of the electric vehicle is,
Being a feed segment in which the electric vehicle is located
A wireless charging and feeding system for an electric vehicle, characterized in that. The method of claim 10,
The information of the current collector,
The type of the current collecting device or the height of the current collecting device from the ground
A wireless charging and feeding system for an electric vehicle, characterized in that. The wireless charging and feeding system of claim 1, as a method of controlling power feeding,
(a) detecting, by the inverter, a position of the electric vehicle when an electric vehicle equipped with a current collector enters a power supply section controlled by the inverter;
(b) determining, by the inverter, information on a current collector installed in the electric vehicle;
(c) converting, by the inverter, a point at which the electric vehicle is located into a charging mode, and controlling power to be supplied to the position according to the determined current collecting device information; And,
(d) the inverter, when the electric vehicle leaves the location, switching the location to an off mode to cut off power at the location
Containing, the power supply control method of the wireless charging power supply system. The method of claim 13,
The location of the electric vehicle is,
Being a feed segment in which the electric vehicle is located
Power supply control method of a wireless charging power supply system, characterized in that. The method of claim 13,
The information of the current collector,
The type of the current collecting device or the height of the current collecting device from the ground
Power supply control method of a wireless charging power supply system, characterized in that. The method of claim 13,
When the feed cable is composed of n (n≥2) pairs of coils,
Each coil can independently adjust the current phase by means of a relay,
Any combination of 0 degree or 180 degree phase is possible for the n pairs of coils,
The inverter controls the wireless power supplied through the feed cable by controlling the current phase combination.
Power supply control method of a wireless charging power supply system, characterized in that.

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